JP2000261462A - Wireless packet communication system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To greatly reduce the power consumption by discriminating reception stop when a header of a high-order layer is received. SOLUTION: An error check code for a header is added to the end of a protocol header for layers higher than a physical layer 101 in a packet. When a protocol in a layer higher than the physical layer 101 checks an address and control information in the header at the reception of the packet so as to confirm that the header is invalid or when the validity of the address and the control information is confirmed by the error check code and it is discriminated that the address is not addressed to itself or the control information is not acceptable for itself, an instruction of stopping the reception is sent to the physical layer 101.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wireless packet communication system for performing mutual communication by packetizing data using wireless, for example.

[0002]

2. Description of the Related Art Wired LANs have been widely used as communication means between information processing apparatuses. The wired LAN is now capable of high-speed communication such as several Gbps (bits per second), and its speed and function are being further enhanced.

However, on the other hand, some problems of the wired LAN are being pointed out. For example, there are great restrictions on the complexity of cable installation and maintenance, as well as the location and relocation of information processing equipment connected to the LAN. In addition, there are various problems due to the wired connection. There is.

[0004] In recent years, the types of information processing devices have also become diverse. For example, even with a personal computer (hereinafter, referred to as a personal computer) as an example, portable devices such as notebook computers as well as desktop computers are rapidly spreading. If this kind of portable information processing device is used while keeping the feature of being portable, it is practically impossible to connect to a wired LAN.

[0005] In order to cope with this, attention has been paid to a wireless LAN which is a wireless LAN. Wireless LAN can eliminate various problems associated with cable laying, and can make the most of the portability of information processing equipment to be used.
Since it is possible to perform communication that could not be performed with a wired LAN, it is expected that technical development related to this wireless LAN will further advance in the future.

Under these circumstances, the working group 11 (IEEE 802.11) of the IEEE 802 standardization committee has focused on the protocol of the wireless LAN, focusing on the physical layer and the medium access control (MAC) sublayer specifications. ) Are being standardized.

[0007]

SUMMARY OF THE INVENTION For example, 802.11
FIG. 2 shows the structure of a packet composed of an information part for the physical layer and an information part for the upper layer defined by the standard. First, there is a preamble (201) for synchronization of the physical layer,
Next, there is a frame start flag called SFD (202), followed by physical layer packet handling information called PLCP header (203).

[0008] The PLCP header includes a physical layer type,
It contains the symbol rate of the upper layer information section and the number of symbols of the upper layer information section. Immediately after the PLCP header, CRC16 (204) is added as an error detection code. The above is collectively referred to as an information section for a physical layer.

[0009] After the PLCP header and CRC16, the upper layer information section starts and continues to the end of the packet. At the top, a header (205) for the upper layer is stored, followed by data (206) of the upper layer, and finally, a CRC32 (207) as an error detection code for the header and data of the upper layer. Is added. In the header of the upper layer, packet handling information for the upper layer,
In particular, control information (208), packet duration (209), and destination address (210) are stored. Other information is expressed as other (211).

When receiving a packet, first, the physical layer establishes signal synchronization with a preamble, detects SFD, and performs symbol synchronization. Next, the PLCP header is read and the symbol rate and the number of symbols used in the upper layer information section are determined. Then, an error check of the PLCP header is performed by the CRC 16, and if there is no error, the upper layer information section is demodulated. , And the resulting symbols are sequentially sent to the upper layer. If an error is detected by the error check by the CRC 16, the reception is stopped immediately and the error is reported to the upper layer.

The upper layer extracts control information, packet duration, destination address, and other information from the upper layer header at the beginning of the symbol sent from the physical layer. Thereafter, the process proceeds to the end of the packet while receiving the data portion of the upper layer. If the CRC 32 check reveals that there is no error, the control information and the destination address taken out earlier may be valid. I understand.

Therefore, if the packet is of a type acceptable to the user and the packet is addressed to the user, the symbol in the data portion for the upper layer is processed to perform one reception. Ends.

The upper layer determines whether the packet is not addressed to itself, is not of an acceptable type,
If an error is found in the inspection of C32, the data section is discarded.

The problem here is that the packet is not addressed to itself, is not of an acceptable type, or an error is found in the CRC 32 inspection as described above. That is, it cannot be determined until all the packets are actually received and the inspection of the CRC 32 is completed. The address and packet type can be determined when the upper layer captures the upper layer header. However, if the CRC 32 at the end of the packet is not checked, the information is really correct or an error. This is because it cannot be determined whether the information is false information.

Under such circumstances, even if a packet is not addressed to itself, a packet type that cannot be accepted by itself, or a packet in which the upper layer header part is in error due to an error,
If it is not received until the end, it cannot be determined. In this case, it is extremely difficult to reduce the power consumption because the danger of dropping the packet destined for the user cannot be avoided without receiving all the packets that frequently fly.

Therefore, the present invention improves the packet structure,
An object of the present invention is to provide a wireless packet communication system in which power consumption due to unnecessary packet reception is suppressed by sending an instruction to stop reception to the physical layer when it is determined that the packet is inappropriate.

[0017]

SUMMARY OF THE INVENTION In order to achieve the above-mentioned object, the present invention is a wireless packet communication system for packetizing data to be transmitted using a wireless medium such as radio waves or light and performing mutual communication. An error detection code for the header is added to the end of the header for the upper layer protocol following the information part for the physical layer in the packet. When a packet is received, a protocol of a higher layer of the physical layer checks the address and control information in the header, and confirms that the address and control information are valid by the error detection code, and When it is determined that the control information is not addressed to itself or is not control information acceptable to itself, an instruction to stop reception is sent to the physical layer.

Further, the present invention provides a method for receiving a message from a physical layer when the protocol of one higher layer of the physical layer confirms that the header is invalid by an error detection code added to the header for the upper layer. I send a stop instruction.

With the above arrangement, when the error detection code added to the header of the upper layer is read, it is possible to determine whether the information in the header is valid or invalid due to an error. If the packet is unnecessary or invalid, a stop instruction can be issued to the physical layer at that time, and thereafter, both the physical layer and the upper layer can maintain the low power consumption state until the next packet, so that Power consumption can be reduced.

[0020]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a schematic configuration diagram for explaining an embodiment of a packet communication system according to the present invention. The configuration of the packet communication system according to the present invention is roughly divided into a physical layer 101 and an upper layer. 102, a data bus 103 between the physical layer and the upper layer, a physical layer control line 104 from the upper layer, and a receiving antenna 105.

FIG. 2 is a diagram showing a packet structure defined in the 802.11 standard. Exit into the air from the left.
The details have already been described in "Problems to be Solved by the Invention". The physical layer and higher layer packet reception operations in this figure have already been described in "Problems to be Solved by the Invention".

FIG. 3 is a diagram showing a packet structure according to the present invention. Since most parts are the same as those in FIG. 2, repeated description of overlapping parts will be avoided, and only newly added parts will be described.
It is an upper layer header error detection code 315 added immediately after the upper layer header.

Hereinafter, a more detailed embodiment of the present invention will be described with reference to FIGS.

When receiving a packet, the CRC 16
This is the same as the conventional technique (FIG. 2) up to the detection of the error in the physical layer header. If no error is detected by the CRC16 check, the physical layer starts demodulation of the upper layer data portion and sequentially transfers the obtained symbols to the upper layer.

The upper layer extracts control information, packet duration, destination address, and other information from the header of the upper layer at the beginning of the symbol sent from the physical layer. Further, the error detection code of the header part is calculated by itself. When the reading of the header section is completed,
Next, the error detection code of the header portion transferred from the physical layer is compared with the error detection code calculated by itself.

As a result of the comparison, if the two error detection codes do not match, it is known that the upper layer header has been damaged by an error that has occurred somewhere in the middle of the transmission path. To stop the reception and shift to the low power consumption state. Also,
If there is a packet that has been successfully received without error before the packet being received, the end timing of the currently received packet can be calculated using the information on the packet duration extracted from that packet. In such a case, in such a case, it is possible for itself to shift to the low power consumption state until the end timing.

As a result of the comparison, if the two error detection codes match, it is known that there is no error in the upper layer header, so that it is guaranteed that various information extracted from the header is also correct. Then, the process proceeds to the determination stage using the various information.

Information such as control information, packet duration, and destination address has already been extracted from the header.
The destination address in the address is checked, and if it is determined that the packet is addressed to itself, reception is continued.

However, if the destination address does not point to itself, there is no point in continuing to receive further.
It instructs the physical layer to stop receiving and shift to the low power consumption state. It is also possible to calculate the end timing of the packet currently being received from the packet duration and then shift to the low power consumption state until that timing.

Further, even if it is found from the control information that the packet is not related to itself, it is meaningless to continue receiving the packet any more. Instruct to move to. It is also possible to calculate the end timing of the packet currently being received from the packet duration and then shift to the low power consumption state until that timing.

Note that, depending on the control information and the destination address,
If it turns out that the packet being received is for broadcast, it may be necessary to continue receiving.

Further, the error detection code for the upper layer header used in the above can be diverted to the existing CRC 32, but there is no inconvenience even if other check codes are used.

[0034]

As described above, according to the present invention,
When reading up to the error detection code added to the header of the upper layer, it is possible to determine whether the information in the header is valid or invalid due to an error. If there is, the physical layer and the upper layer can be instructed to stop at that point in time. Thereafter, the physical layer and the upper layer can maintain the low power consumption state until the next packet.
As compared with the case where reception is continued up to 2, power consumption can be significantly reduced. Since 80% of the power consumption of the system is consumed in reception, the effect of reducing power consumption during reception in the present invention is very large.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram illustrating an embodiment of a packet communication system in a wireless LAN according to the present invention.

FIG. 2 is a diagram illustrating the structure of a conventional (IEEE 802.11) packet.

FIG. 3 is a diagram illustrating the structure of a packet according to the present invention.

[Explanation of symbols]

 Reference Signs List 101 physical layer 102 upper layer 103 data bus between physical layer and upper layer 104 physical layer control line 105 from upper layer 105 receiving antenna 201 preamble 202 SFD 203 PLCP header 204 CRC16 205 upper layer header 206 upper layer data 207 CRC32 208 Control information 209 Packet duration 210 Destination address 211 Others 301 Preamble 302 SFD 303 PLCP header 304 CRC16 305 Upper layer header 306 Upper layer data 307 CRC32 308 Control information 309 Packet duration 310 Destination address 311 Others 312 Upper layer header Error detection code

Claims (2)

[Claims] 1. In a wireless packet communication system for packetizing data to be transmitted using a wireless medium such as radio waves or light and performing mutual communication, a layer higher than the physical layer is provided after a physical layer information storage section in a packet. A header for the protocol of the above is arranged, and an error detection code for the header is added to the end of the header. When a packet is received, a protocol of a higher layer of the physical layer has an address and control information in the header. And when the error detection code confirms that the address and control information are valid, and when it is determined that the address is not addressed to itself or is not an acceptable packet, the physical A wireless packet communication system characterized by sending an instruction to stop reception to a layer. 2. When receiving a packet, if a protocol in a higher layer than a physical layer confirms that the header is invalid by the error detection code, a transmission stop instruction is sent to the physical layer. The wireless packet communication system according to claim 1, wherein